EP0191947A1

EP0191947A1 - An apparatus for compensating a quantization error

Info

Publication number: EP0191947A1
Application number: EP85116473A
Authority: EP
Inventors: Yasuo C/O Sony Corporation Nagai; Fumiyoshi C/O Sony Corporation Abe
Original assignee: Sony Corp
Current assignee: Sony Corp
Priority date: 1984-12-25
Filing date: 1985-12-23
Publication date: 1986-08-27
Anticipated expiration: 2005-12-23
Also published as: CA1265186A; US4694234A; KR860005354A; AU5167285A; JPH06101948B2; EP0191947B1; JPS61151716A; ATE64015T1; DE3583025D1; KR950000418B1; AU584151B2

Abstract

@ An apparatus for compensating for a quantization error having a time detector circuit (30) for detecting a time signal on the basis of the number of clock signals (CLK) which arrive within the time period thereof, a quantization error detector circuit (40) for making a quantization error time corresponding to a time difference between the time signal and the clock signal as an analogue voltage value, and a compensator circuit (50) for compensating for a digital detected time derived from the time detector circuit (30) on the basis of an analogue quantization error time from. the quantization error detector circuit (40).

Description

BACKGROUND OF THE INVENTIOF

Field of the Invention

This invention relates generally to an apparatus for compensating a quantization error and more particularly is directed to an apparatus for compensating a quantization error for use with a servo system of a video tape recorder (VTR).

Description of the Prior Art

In the prior art, a time information detecting apparatus which detects a time information such as a pulse width of a pulse signal is employed in various kinds of apparatus and which is also applied to a servo system for a motor of a video tape recorder (VTR).
In the VTR, as shown in Fig. 1 in order to rotate a DC motor 1 such as a drum motor, a capstan motor and so on at a same rotational speed, the rotational speed of the motor 1 is detected by a frequency generator (FG) 2 and a control voltage signal corresponding to the detected rotational speed (time information) is generated by a time information apparatus 3 and is supplied through a motor drive amplififying circuit 4 to the motor 1.
As the time information detecting apparatus 3 used in such speed servo system, there is known such one that is constructed as shown in Fig. 2.
Referring to Fig. 2, a time signal VEL (Fig. 3A) consisting of a pulse signal from the frequency generator 2 (Fig. 1) is supplied to a delay circuit 5 and to a sampling pulse generator circuit 8. The delay circuit 5 generates a timing delay signal DLY (Fig. 3B), which rises to logic a level "E" during a predetermined time TO from every other rising-up time point tl of the time signal VEI. to the logic level "H" and supplies the signal DLY to a slope generator circuit 6. The slope generator circuit 6 supplies to a sample and hold circuit 7 a voltage signal V which gradually and rectilinearly increases in voltage value from a time point t2 at which the timing delay signal DLY is fallen to a logic "L" as shown in Fig. 3C.
A sampling pulse generator circuit 8 receives the time signal VEL, detects a rising edge time point t3 of the time signal VEL delayed by a delay amount of one period TX from the timing point tl at which the timing delay signal DLY rises to the logic "H", produces a sampling pulse signal SMP shown in Fig. 3D and supplies the sampling pulse signal SMP to the sample and hold circuit 7.
The sample and hold circuit 7 is adapted to sample and to hold the value of the voltage signal V when the sampling pulse signal SMP is applied thereto and generates the value thereof as a control voltage signal VCON (Fig. 3C).
Consequently, according to the time information detecting apparatus 3 in Fig. 2, when the motor 1 is rotated at a speed higher than a predetermined rotational speed, the period TX of the time signal VEL becomes short and hence the sampling pulse signal SMP is delivered at an early time point, so that the sample and hold circuit 7 produces the control voltage signal VCON of a low level. On the other hand, when the motor 1 is rotated at a rotational speed lower than the predetermined rotational speed, the period TX of the time signal VEL becomes long so that the sample and.hold circuit 7 produces the control voltage signal VCON of a high level.
Therefore, the motor 1 is controlled so as to be rotated at the same rotational speed.
However, if such time information detecting apparatus 3 is formed as an analogue circuit arrangement, there occurs an defect that the output voltage signal will be fluctuated due to the change of ambient temperature, the fluctuation of a power supply source voltage and so on, and hence the voltage is unstable.
For this reason, it may be considered that this time information detecting apparatus 3 be formed as a digital circuit arrangement. According to such digital time information detecting apparatus, since the time information of the analogue amount is digitized, a quantization error occurs so that the accuracy of the output signal is restricted by this quantization error. Accordingly, in order to control, for example, the motor stably, a clock frequency must be selected high.
For example, if a drum motor in which the period of the pulse signal VEL from the frequency generator 2 is 50ps is stably controlled at an accuracy of within 0.02%, it is necessary to detect the period as accurately as more than 5000 counts. This requires the clock frequency expressed by the following Eq. (1)
1/50 (us) x 5000 - 100 (MHz) ... (1)
However, since the maximum operation frequency of a digital IC widely used lies in a range from about 10 to 20 MHz, if the clock frequency of 100 MHz is intended to be realized, there is a fear that a digital IC, which can be applied to such purpose, will not be obtained in practice. Further, even if the clock frequency of 100 MHz may be realized, the apparatus becomes complicated in construction and large in size because many interface circuits are required by each circuit and also such apparatus comsumes a large power. Therefore, such apparatus is not suitable in practice.

OBJECTS AND SUMMARY OF THE INVENTION

Accordingly, it is an object of this invention to provide an apparatus for compensating for a quantization error which can stably operate regardless of the change of temperature, the fluctuation of a power source voltage and so on.
It is another object of this invention to provide an apparatus for compensating for a quantization error of a simple circuit arrangement which can produce a detected value of high resolution..
It is a further object of this invention to provide an apparatus for compensating for a quantization error which is suitable for use with a servo system of a video tape recorder.
According to one aspect of the present invention, there is provided an apparatus for compensating a quantization error which comprises a time detector circuit for detecting a time signal on the basis of the number of clock signals arriving within the time thereof, a quantization error detector circuit for producing quantization error times corresponding to a time difference between the time signal and the clock signal as an analogue voltage value and a . compensator circuit for compensating for a digital detection time derived from the time detector circuit on the basis of an analogue quantization error time from the quantization error detector circuit.
In this case, a time indicated by the time signal is detected by the time detector circuit 30 using the clock signal CLK . As a result, the circuit arrangement can be formed as a digital circuit arrangement so that the detected result is given a stability against the change of temperature and the fluctuation of a power source voltage.
However, when the circuit is formed as the digital circuit arrangement, the quantization time errors will occur. Therefore, by the quantization error detector circuit, the quantization time errors are detected as the analogue voltage according to the analogue circuit arrangement and on the basis of the detected voltage, the detected time signal is compensated for by the compensator circuit.
As a result, the quantization time errors, which will inevitably occur because of the digital circuit arrangement, can be removed from the detected time signal so that it is possible to obtain a detected output of high accuracy.
These and other objects, features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments taken in conjunction with the accompanying drawings, throughout which like reference numerals designate like elements and parts.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a block diagram showing a circuit arrangement of a case in which a prior art time information detecting apparatus is applied to a motor speed control apparatus;
Fig. 2 is a block diagram showing an example of a prior art time information detecting apparatus;
Figs. 3A to 3D are timing charts useful for explaining the operation of the apparatus of Fig. 2, respectively;
Fig. 4 is a block diagram showing an embodiment of an apparatus for compensating for a quantization error according to the present invention;
Figs. 5A to 5G are timing charts useful for explaining the operation of the apparatus shown in Fig. 4, respectively; and
Fig. 6 is a block diagram showing another embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Now, the present invention will hereinafter be described with reference to the attached drawings, in which the present invention is applied to the speed servo system of a VTR. Fig. 4 is a block diagram showing an embodiment of an apparatus for compensating for a quantization error according to this invention.
Referring to.Fig. 4, two frequency generators 2A and 2B are mounted on a drum motor 1 such that phases of output signals S2A and S2B from the frequency generators 2A and 2B become different from each other by 90°. The output signals S2A and S2B from the frequency generators 2A and 2B are supplied to comparator circuits 10A and 10B, respectively.
The comparator circuits 10A and 10B compare the output signals S2A, S2B with a reference voltage VREF and reshape them into pulse signals S10A and S10B, respectively. The pulse signals S10A and S10B reshaped are fed to an exclusive-OR circuit 11. The exclusive-OR circuit 11 supplies an exclusive-OR signal of the pulse signals S10A and S10B to a time information detecting apparatus 20 as an original time signal VEL1 which is to be detected (Fig. 5D).
In the time information detecting apparatus 20, a D-type flip-flop circuit 31 in a time detector circuit 30 is supplied at its data input terminal D with the original time signal VEL1 and at its clock input terminal with a clock signal CLK having a frequency of 7 MHz (Fig. 5A). This flip-flop circuit 31 is triggered at the leading edge of the clock signal CLK, generating a synchronized time signal VEL2 (Fig. 5C), which is provided by synchronizing the original time signal VEL1 with the clock signal CLK, as a Q output. This signal VEL2 is fed to a 2-input AND circuit 32 at its one input terminal as a gating signal.
Since the AND circuit 32 is supplied at the other input terminal with the clock signal CLK, the AND circuit 32 allows the clock signal CLK to pass therethrough during a period T2 in which the synchronized time signal VEL2 rises to the logic level "H". The clock signal CLK therefrom is fed to a counter 33.
The counter 33 is adapted to carry out the count operation each time the clock signal CLK is supplied thereto and a latch circuit 34 latches the counted value of the counter 33 when the latch circuit 34 is supplied with a latch signal LAT (Fig. 5F) and delivers the same to a D/A (digital-to-analogue) converter circuit 35.
The D/A converter circuit 35 converts a latched output CNTX from the latch circuit 34 to an analogue signal and delivers the same as an output signal VOUTO from a time detector circuit 30. This signal VOUTO is supplied through an adder circuit 52 and the motor drive amplififying circuit 4 to the motor 1 as the speed control signal.
A reset signal RST (Fig. 5G) for resetting the counter 33 and the latch signal LAT for specifying the latch timing of the latch circuit 34 are both generated from a control signal generator circuit 36. The control signal generator circuit 36 receives the synchronized time signal VEL2 and the clock signal CLK, detects the trailing edge of the synchronized time signal VEL2 and supplies to the latch circuit 34 the latch signal LAT (Fig. 5F) which rises up at a time point t8 succeeding to a falling down time point t7 of the synchronized time signal VEL2 in synchronism with the clock signal CLK.
Accordingly, the counted value CNTX of the counter 33 at the time point t8 at which the latch signal LAT is fed to the counter 33 becomes the value corresponding to the rising period T2 of the synchronized time signal VEL2. When the motor 1 is rotated at a rotational speed higher than the predetermined rotational speed, the rising-up time period T2 is short so that the counted value CNTX which is latched is small and hence the speed control signal VOUTO of a low level is fed back to the motor 1. When on the other hand the motor: 1 is rotated at a rotational speed lower than the predetermined rotational speed, the rising-up period T2 becomes longer so that the counted value CNTX is large and hence the speed control signal VOUTO of a high level is fed back to the motor 1.
The control signal generator circuit 36 generates the reset signal RST (Fig. 5G) which rises up at a time point t9 delayed from the time point t8 at which the latch signal LAT_. is produced, in synchronism with the clock signal CLK. Accordingly, the counter 33 is reset after the latch operation was carried out by the latch circuit 34 positively. The output time point t9 of the reset signal RST is selected to be preceding a time point at which the synchronized time signal VEL2 rises up next time.
Although in Fig. 4 it may be considered that as the gating signal for controlling the AND circuit 32 to open, the original time signal VEL1 is directly used to allow the clock signal CLK to pass during the rising-up time period thereof and to be fed to the counter 33, if the original time signal VEL2, which is provided by synchronizing the original time signal VEL1 with the clock signal CLK, is used as the gating signal as shown in Fig. 4, it is possible to prevent the original number of the clock signals CLK passing during the rising-up time period Tl of the original time signal VEL1 from being increased or decreased.
By the way, the rising-up time period Tl of the original time signal VEL1 is the analogue amount which continuously varies with the change of the rotational speed of the motor 1. Whereas, the time period appearing on the practically detected value, i.e., the rising-up time period T2 of the synchronized time signal VEL2 becomes a time period equal to a time period, which is provided by multiplying the period of the clock signal CLK, and which changes stepwise. Consequently, as shown in Figs. 5D and 5E, quantization error time periods TH and TL occur in the rising-up and falling-down portions of the original time signal VEL1. The apparatus for compensating for a quantization error shown in Fig. 4 includes, in addition to the above mentioned circuit arrangement, a quantization error detector circuit 40 for detecting the quantization error time periods and a compensator circuit 50 for compensating for such eriors.
In the quantization error detector circuit 40, 2-input AND circuits 41 and 42 are adapted to detect the error time period TH at the rising edge portion and the error time TL at the falling-down portion of the origianl time signal VEL1, respectively.
The AND circuit 41 is supplied at its one input terminal with the original time signal VELl (Fig. 5B) and at its other input terminal with an inverted signal VEL2 of the synchronized time signal VEL2 (Fig. 5C). Accordingly, the AND circuit 41 produces a leading edge error time signal ERRH (Fig. 5D) which is delivered to a first constant current circuit 43. On the other hand, the AND circuit 42 is supplied at its one input terminal with an inverted signal VELl of the original time error signal VEL1 and its other input terminal with the synchronized time signal VEL2. Thus the AND circuit 42 produces a trailing edge error time signal ERRL (Fig. 5E) which is delivered to a second constant current circuit 44.
The first constant current circuit 43 is adapted to supply a constant current 10 to a capacitor C and to charge it during the leading edge error time period TH in which the leading edge error time signal ERRH rises up to the logic "H". While, the second constant current circuit 44 is adapted to flow a constant current Il so as to discharge the capacitor C during the trailing edge error time period TL in which the trailing edge error time signal ERRL rises up to the logic "H". Accordingly, a voltage V_C across the capacitor C after the charging and discharging operations of the capacitor C were ended takes a voltage value corresponding to a time difference (TH - TL) between the leading error time period TH and the trailing error time period TL. Since the time period difference (TH - TL) is equal to the time period difference (Tl - T2) between the rising-up period Tl of the original time signal VEL1 and the rising-up period T2 of the synchronized time signal VEL2, a voltage value corresponding to a total quantization error time period (Tl - T2) remains in the capacitor C. This residual voltage V_c is supplied to the compensator circuit 50 as an error time period detecting voltage signal.
The capacity of the capacitor C and the constant currents 11 and 10 flowing through the capacitor C are selected such that the residual voltage of the capacitor C per unit time may become equal to a voltage of the speed control signal VOUTO generated from the D/A converter circuit 35 per unit time.
In the compensator circuit 50, a sample and hold circuit 51 is adapted to sample and hold the error time period detecting voltage signal V_c from the capacitor C and to deliver the same thus held to an adder circuit 52 when it is supplied with the latch signal LAT (Fig. 5F) from the control signal generator circuit 36.
Accordingly, the adder circuit 52 compensates for the quantization error by adding the control voltage signal VOUTO corresponding to the rising-up time period T2 of the synchronized time signal VEL2 with the voltage signal VC corresponding to the quantization error time period (Tl - T2). Thus, the adder circuit 52 produces the control voltage signal VOUT1 corresponding to the rising-up time period Tl of the origianl time signal VELl.
Further in Fig. 4, a switching circuit 45 i's connected in parallel to the capacitor C. When this switching circuit 45 is supplied with the reset signal RST (Fig. 5G) from the control signal generator circuit 36, it is closed during a predetermined time period. Due to the closing operation of the switching circuit 45, the capacitor C completely discharges the accumulated charges and is placed in the standby mode for the charge and discharge operation of the next period of the original time signal VEL1.
According to the circuit arrangement of Fig. 4, when the motor 1 is rotated and hence the original time signal VELl is supplied to the time information detecting apparatus 20, in the time information detecting apparatus 20, the original time signal VELl is synchronized with the clock signal CLK by the D-type flip-flop circuit 31 and then the rising_-up time period T2 of the synchronized time signal VEL2 is counted by the counter 33. The counted value is latched by the latch circuit 34 at the time point t8 and is then converted to the analogue voltage signal VOUTO by the D/A converter circuit 35, which is then fed to the adder circuit 52.
When the original time signal VELl is fed to the time information detecting apparatus 20, in the quantization error detecting apparatus 40, the rising error time signal ERRB is supplied from the AND circuit 41 to the constant current source circuit 43 during the error time period TH from the time point t4, driving the constant current circuit 43 so as to charge the capacitor C. Then, during the error time period TL from the time point t6, the trailing edge error time signal ERRL is supplied from the AND circuit 42 to the constant current circuit 44, driving the constant current circuit 44 so as to discharge the capacitor C. Thereafter, at the time point t8, the voltage V_c across the capacitor C is sampled and then held by the sample and hold circuit 51, which is then delivered to the adder circuit 52.
Accordingly, from the time point t8, the adder circuit 52 produces the speed control signal VOUT1 the quantization error component of which is compensated for by adding the voltage signal VC to the speed control signal VOUTO. This speed control signal VOUT1 is fed back through the amplifying circuit 4 to the motor 1, by which the motor 1 is controlled.
Thereafter, at the time point t9, the reset signal RST is fed to the counter 33 and the switching circuit 45, clearing the counted value of the counter 33 and restoring the value of the voltage across the capacitor C to the reference value (for example, 0V), thus setting the time information detecting apparatus 20 in a standby mode for the next period of the original time signal VEL1.
As described above, according to the apparatus of Fig. 4, the quantization time period error (TH - TL)(= Tl - T2) is detected in the form of the analogue amount as the voltage V_c across the capacitor C and the time signal VOUTO measured in a digital fashion is compensated for by this detected amount, so that it is possible to obtain a measuring time which is accurate enough for the measuring time of the origianl time signal VEL1. In this case, if the accuracy sufficient for the practical use is merely obtained by the apparatus of digital circuit arrangement, it is necessary to select the frequency of the clock signal CLK to be, for example, 100 MHz that can not be realized. However, since the apparatus for compensating for a quantization error of the present invention includes the quantization error detector circuit 40 and the compensator circuit 50, in order to achieve the same accuracy, it is sufficient to select the frequency of the clock signal CLK to be, for example, about 7 MHz. Thus, the circuit arrangement can be made practical and simple in construction.
According to the circuit arrangement of Fig. 4, since the time signal detected with high accuracy is used as the speed control signal of the motor 1, it is possible to increase the accuracy of the rotational speed of the motor 1.
While in the above mentioned embodiment the time information detecting apparatus 20 is applied to the speed control apparatus of the motor 1, the present invention is not limited to the above mentioned apparatus but can be widely applied to such apparatus which must be arranged such that the time of a time signal is measured and then delivered as an electrical signal. For example, this invention can be applied to such control apparatus that a phase difference between two signals is measured as a time signal and the control operation is carried out so as to remove such phase difference. Also, the present invention can be applied to a case in which a time signal to be measured is such one with a total amount of more than two rising periods.
Further, while in the above mentioned embodiment the time signal, which is measured by the digital circuit arrangement and is compensated for by the analogue circuit arrangement, is delivered in the form of the analogue amount from the output stage, the present invention is not limited to the above mentioned embodiment but can be applied to a case in which such signal is produced in the form of digital amount from the output stage in accordance with the usage. For example, when a detected time signal is supplied to a display apparatus so as to display the measured time thereon, it is practical to generate the time signal in the form of the digital amount.
When the measured time signal is delivered in the form of the digital amount, instead of the circuit arrangement formed of the D/A converter circuit 35, the analogue adder circuit 52 and the sample and hold circuit 51 shown in Fig. 4, there can be used such a circuit arrangement as shown in Fig 6 showing a main part of another embodiment of according to the present invention. In the apparatus of Fig. 6, the voltage V_c across the capacitor C (Fig. 4) is converted to a digital signal VCD by an A/D converter circuit 60. The digital signal VCD is latched by the latch circuit 61 at the timing of the leading edge of the latch signal LAT and the digital signal latched is added to the latch output CNTX from the latch circuit 34 (Fig. 4) in a digital adder circuit 62 and thereby the measured time is delivered as a digital signal VODT1D.
According to the present invention as set forth above, since the time signal can be measured by means formed of the digital circuit arrangement and the quantization error caused upon the measurement can be detected and compensated for by means formed of the analogue circuit arrangement, the apparatus of the invention can stably be operated regardless of the change of temperature and the fluctuation of the power supply voltage. In this case, although the means formed of the digital circuit arrangement is employed, it is'possible to obtain the apparatus for compensating for a quantization error which can produce the detected value of high resolution. Consequently, although the frequency of the clock signal used for the digitalization is selected to be within the operation frequency of the ordinary digital IC, it is possible to obtain the satisfactory accuracy.
The above description is given on the preferred embodiments of the invention but it will be apparent that many modifications and variations could be effected by one skilled in the art without departing from the spirits or scope of the novel concepts of the invention so that the scope of the invention should be determined by the appended claims only.

Claims

1. An apparatus for detecting a pulse width of a pulse signal characterized in:

a) means for generating reference clock pulses (CLK);

b) means (33, 34, 35) for counting a number of said reference clock pulses during a generation of a pulse signal, said counting means (33, 34, 35) producing a value of counts indicating a pulse width of said pulse signal;

c) means (40) for detecting a phase difference between said reference clock pulses and said pulse signal and generating an analogue data corresponding to said phase difference; and

d) means (50) for compensating said value of counts in response to said analogue data to thereby generate a pulse width data having a less quantization error.

2. The apparatus according to claim 1, characterized in that said phase difference detecting and analogue data generating means (40) includes a first detector (41) for detecting a phase difference between said clock pulse and a rising edge portion of said pulse signal, a second detector (42) for detecting a phase difference between said clock pulse and a trailing edge portion of said pulse signal, and a converting circuit (C, 43, 44) for converting a difference signal between phase differences derived from said first and second detectors to said analogue data (VC).

3. The apparatus according to claim 2, characterized in that said converting circuit includes a capacitor (C) and charge and discharge circuits (43, 44) for charging and discharging said capacitor (C) in response to said output signals (ERRH, ERRL) of said first and second detectors (41, 42), respectively.

4. The apparatus according to anyone of claims 1 to 3, characterized in that said counting means includes a counter (33), a latch circuit (34) connected to said counter (33) and a digital-to-analogue converter (35) connected to said latch circuit (34).

5. The apparatus according to claim 4, characterized in that said compensating means (50) includes an adder circuit (52) for adding said analogue data (VC) to an output signal (VOUTO) of said digital-to-analogue converter (35).

6. The apparatus according to claim 4, characterized in that said compensating means includes an analogue-to- digital converter (60) connected to said detecting means (40), a latch circuit (61) connected to said analogue- to-digital converter (60) and a digital adder (62) for digitally adding the output of said latch circuit (61) to a digital output of said latch circuit (34) of said counting means, its said digital-to-analogue converter (35) being omitted.

7. A servo circuit for controlling a motor (1), characterized in :

i) means (2A, 2B, 10A, 10B, 11) for generating a pulse signal indicating a rotation speed of said motor;

ii) an apparatus for detecting a pulse width of said pulse signal according to anyone of claims 1 to 6, and

iii) means (4 ) for driving said motor (1) in response to an output signal (VOUT1) of said compensating means (50) of said apparatus